International Journal of Engineering Materials and Manufacture (2023) 8(3) 51-66 

https://doi.org/10.26776/ijemm.08.03.2023.01 

 

M. Hazra , A. K. Singh 

Defence Metallurgical Research Laboratory (DMRL)P.O. Kanchanbagh, Hyderabad 500 058, India 

E-mail: mhazra@dmrl.drdo.in 

 

Reference: Hazra and Singh (2023). Failure Investigation on Failed Towing Arm of An Aircraft: A Case of Improper Material 

Processing and Failed Repair Welding of a Cast Al-Cu-Si Type Aluminium Alloy. International Journal of Engineering Materials and 

Manufacture, 8(3), 51-66. 

 

 

Failure Investigation on Failed Towing Arm of an Aircraft: A Case of 

Improper Material Processing and Failed Repair Welding of a Cast Al-Cu-Si 

Type Aluminium Alloy 

 

 

Mrityunjoy Hazra and Ashok Kumar Singh 

 

 

Received: 01 March 2023 

Accepted: 19 May 2023 

Published: 01 July 2023 

Publisher: Deer Hill Publications 

© 2023 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

Present work describes the metallurgical failure investigation of a failed towing arm/bar. Aircraft attached with this 

incident travelled a distance of 2 km with normal towing speed (8 km/hr). The component is said to have broken 

while turning to right from taxi track and then turning left about 15-20
o
. The mating fracture pieces of the failed 

towing arm fork along with bent towing pin were analyzed for failure investigation. Parent material of the towing 

arm has been found to be a cast Al-Cu-Si alloy closely matching with the alloy 295 used in T6 condition. Pin is made 

of mild steel. Failure of the towing arm fork has been initiated by weld solidification cracking of the weld region at 

close to the fusion line. Liquation cracks at heat affected zone (HAZ) have aggravated the situation further by 

weakening the microstructure and facilitating the crack propagation. Grain boundary precipitates of Al-Cu-Fe type in 

HAZ have facilitated the propagation of failure along with the liquation cracking. On the other hand, Al-Fe-Mn type 

of precipitates sitting along the grain boundaries in weld area seems to have not facilitated the failure initiation unlike 

the solidification cracking. Improper material processing has led to the weakening of the bulk microstructure and thus 

the component itself, by introduction of various defects (pores, grain fall out, thick Al-Cu-Fe type of continuous grain-

boundary precipitates and cracking). Weld repairing has been found to be a failure in Al-Cu-Si system in the present 

component. 

Keywords: Towing arm, cast Al-Cu-Si, repair welding, hot cracking, solidification cracking, liquation cracking, 

intergranular fracture, Al-Cu-Fe grain boundary precipitates, Al-Fe-Mn grain boundary precipitates. 

 

1 INTRODUCTION 

1.1 Background Information 

Generally, aircrafts are shifted from Hanger to Pan (operational parking area / shelters provided by the sites of the 

runway) by towing process. The towing distance depends on the locations of Hanger and Pan. The towing bar broke 

while turning to right from taxi track and then turning left about 15-20
o
. The towing distance for this particular case 

is about 2 km. In further examination, it has been observed that the left side of the towing bar fork end broke during 

towing process on a normal track i.e., without significant slope from taxi track to Pan. The aircraft towed almost 2 

km and towing speed was normal about 8 km/hr. The mating fracture pieces of the failed towing arm fork along 

with bent towing pin were analyzed for failure investigation, while towing spool (part of aircraft which is attached 

with towing arm for pulling it along with tractor) was found to be intact (undamaged) and likewise not destroyed 

for analysis. Present paper is thus concerned with the failure investigation of the failed towing arm fork along with 

bent towing pin. 

 

1.2 Literature Review 

Towing is a method of movement of large aircraft about the airport, flight line and hangar without use of engine 

power of an aircraft [1]. It is commonly carried out by towing with a tow tractor or tug. Hand pushing on the correct 

areas of the aircraft may be helpful in the case of the small aircraft. Certain qualified personnel are also sometimes 

permitted for taxiing the aircraft about the flight line. Reckless or careless duty on towing an aircraft may cause 

hazard, resulting in damage to the aircraft and importantly injury to the personnel. Thus, the specific instructions for 

each model of aircraft as prescribed in the manufacturer’s maintenance manual must be followed. A qualified person 



Failure Investigation on Failed Towing Arm of An Aircraft: A Case of Improper Material Processing and Failed Repair Welding 

52 

is usually within the flight (before the flight is being moved for towing) deck to operate the brakes in case the tow 

bar fails or becomes unhooked. Prevention of possible damage of the aircraft can then be reduced.   

Various types of tow bars available for general use are by and large utilized for towing operations of different 

types. Some special types of bars may be employed on a particular aircraft only. Such types are built by the aircraft 

manufacturer. Obtaining a sufficient tensile strength value to pull most aircraft has traditionally been the principal 

design criteria for these bars and very importantly, torsional or twisting loads are not intended at all. A schematic 

diagram of tow bar assembly is shown in Fig. 1. 

 

Figure 1: Schematic diagram of a tow bar assembly 

 

Two incidents of failures of towing bars in aircraft towing system (ATS) have been reported in open literature, 

although with insignificant metallurgical input [2, 3]. In one case, shear pin broke and caused the failure of the whole 

system in airbus 319 [2]. In another case, shear bolt along with tow bar body broke in case of a Boeing 707 aircraft 

[3]. Fatigue mechanism has been attributed to be the cause of failure. Usually, breakage of a tow bar is not a big issue 

to deal with. One has to replace the tow bar and a few minutes later the aircraft would be back on its way. However, 

it may have sometimes, secondary damaging effect (i.e. damage caused by the failure of tow bars) which may delay 

the flight schedule related activities significantly. One such incident of failure of a nose gear is reported as a result of 

failure of tow bars (would be referred as towing arms, heretofore) [4].  

 

2 EXPERIMENTAL PROCEDURE 

Both the failed towing arm fork and bent towing pin were at first visually examined with the help of naked eye and 

magnifying glass. Photographs were taken in as-received condition from various orientations and preserved for future 

reference during the course of analysis. One of the mating fracture surfaces (dislodged piece) was extracted delicately 

without damaging the surface for further in-depth examination under scanning electron microscope (SEM) equipped 

with electron dispersive spectroscopy (EDS). The fracture surface was examined under SEM after cleaning with 

acetone in an ultrasonic cleaner. Subsequently, a representative cross-sectional sample was extracted from failed parts 

for detailed metallographic investigation. The broken piece of towing arm fork was sectioned into three parts across 

the thickness. It was done very delicately with the sequence of cold mounting followed by sectioning through slow 

speed isomet cutter. The polished sample surfaces were examined under optical microscope and SEM. 

The bent portion of the towing pin was prepared for metallographic study in both the un-etched and etched 

conditions. Keller’s reagent was used for etching the towing arm fork pieces, while 2 % nital was employed as etchant 

for towing pin. Bulk compositional analysis of the failed components was carried out by X-ray florescence 

spectroscopy (XRF) and EDS techniques followed by verification of results with those obtained from inductively 

coupled plasma optical emission spectroscopy (ICP-OES). Vickers hardness readings were taken at 5 kg load on 

metallographically prepared samples. 

 

3 RESULTS 

3.1 Visual Examination 

As-received failed components are shown in Fig. 2. Fractured towing arm fork end bent towing pin along with intact 

(undamaged) towing spool are seen. Red colour paint is seen to cover the entire towing arm fork. Fig. 3 reflects 

fracture surfaces of towing arm fork end in various views. Typical brittle fracture of as-cast products seems to prevail, 

as is typified by coarseness of the fracture features. There is existence of well revealed weld regions in the surroundings 

of the fracture surfaces. Probable detached/peeled off parts during service which seem to have been welded later on 

have been marked (Fig. 3(d, e and f)). These are quite easily identifiable by visibly clear weld beads (boxed). Clear 

visibility is obvious for weld region, base material as well as the heat-affected zone (HAZ) on the failed surfaces (Fig. 

3 (a, b and c)). A prominent secondary crack spanning across the whole fracture surface and almost at boundary 



Hazra, M. and Singh, A. K. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 51-66 

53 

(fusion line) between the weld region and the rest of the cross-section (consisting of HAZ and base material) is seen 

(Fig. 3 (b and c)).  Also, the mating failed surface reveals some small secondary cracks at the welds close to the 

boundaries of weld and HAZ in two perpendicular sides (in 2-dimension) of the failed component (Fig. 3g). These 

cracks are along the weld-HAZ boundary at one side weld as well. Henceforth, weld regions with bigger and smaller 

dimensions at two perpendicular directions are referred as longitudinal and transverse welds, respectively. The 

counterpart of the fracture surface presented in Fig. 3a is shown in Fig. 3h. This is a magnified view of high resolution 

of the portion presented in Fig. 3b. Here, one may notice the disparity between weld thicknesses in longitudinal and 

transverse welds. 

 

3.2 Fractography 

Fractographs are presented in Figs. 4-7 along with EDS analyses. Intergranular fracture features have been found to 

be prevalent. Fig. 4 displays low magnification image showing intergranularity of the fracture surfaces. Figs. 4 and 5 

(a, b and c) represent fracture features from HAZ (marked in Fig. 3b). On the other hand, representation of weld 

fracture is in Fig. 5d. Summary of all the types of fracture features observed at various locations on the surface is 

presented in Fig. 5. Gas-hole and/or porosity have been observed occasionally (boxed region in Fig. 5a). Intergranular 

fracture features is quite noticeable along with shallow rubbing. Deep secondary cracks along the intergranular 

channels have been observed (Fig. 5 (c and d)). Interestingly, this fracture feature also resembles the appearance of 

pores (Fig. 5c). It is to be noted that the type of intergranularity differs in features presented in Fig. 5(b and c) to 

Fig.5d. Signature of cleavage within the intergranular fractures has also been noticed occasionally (Fig. 5 (c and d)). 

Intergranularity in fracture is more vivid in a location presented in Fig. 5d, in contrast to the rubbed intergranular 

fracture of the few other locations observed in Fig. 5c. 

 

 

Figure 2: Photographs of the as-received broken towing arm fork and bent towing pin 

 

 

 
 

Figure 3: Photographs of fracture surfaces of towing arm fork end in various views 

 



Failure Investigation on Failed Towing Arm of An Aircraft: A Case of Improper Material Processing and Failed Repair Welding 

54 

EDS analysis on the location marked as 1 (Fig. 5b) reveals the presence of Al and O majorly (Fig. 6). It basically 

reflects the composition of the tiny round particles present in that location. Fractographs near the weld region (along 

one of the side welds) are shown in Fig. 7. Again, HAZ in this region reflects intergranular fracture, while fracture of 

the weld zone is completely cleavage type. However, intergranular channels are even quite visible within this cleaved 

surface. Very prominent secondary crack has also been observed at the boundary or interface between the weld zone 

and HAZ. 

 

 
 

Figure 4: Low magnification SEM image of fracture surface 

 

 
 

Figure 5: Summarized view of the various types of fractures observed in the present failure 

 

 
 

Figure 6: EDS analysis pattern taken on location 1 (Fig. 5b) 



Hazra, M. and Singh, A. K. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 51-66 

55 

 

 

Figure 7: Fractographs near the weld region 

 

 
 

Figure 8: Cold mount containing towing arm fractured end along with location of the sample in main fractured piece 

 

 

3.3 Metallography 

Towing arm fork (henceforth, it will be referred to as towing arm only) fractured section mounted in cold mount 

along with the schematic view of the location of the sample in main fractured piece is shown in Fig. 8. Existence of 

weld regions at two sides or edges is very clear. This image may be seen along with the as-received photographs 

presented in Fig. 3(a, d-f), so as to have quite a good idea about the relative location of the weld, HAZ and base 

material within the fractured component. It has also been found to contain secondary cracks intermittently, as one 

such is marked in Fig. 8b. It is to be noted that the crack trajectory and orientation of secondary cracks is exactly 

matching with the fracture path (main crack causing the fracture) (Fig. 8). Grain boundary precipitates and occasional 

cracking along these precipitates have been observed throughout the base as well as weld region in the un-etched 

condition (Fig. 9).  

Microstructure exhibits the presence of well revealed weld zone and base material after etching (Fig. 10). Weld 

region contains few dendrites with 90 angle between primary and secondary dendritic arms indicating that the weld 

material is cubic. Interestingly, both the heat affected zone (HAZ) and remaining base material reveal the presence 

of equiaxed grains. Heat-affected zone (HAZ) of a spread of 0.7 mm has been found and contains numerous cracks 

and grain fallouts (Fig. 10). Low magnification SEM images are shown in Fig. 11. Ample of pores has been found in 

both the regions, i.e., weld as well as base material. Amount of pores seems to have been more in weld than that in 

the base material. High magnification images of the weld region and base material are presented in Fig. 12(a, b) and 

Fig. 12(c-e), respectively. Again, area fraction of the cracks is found to be more in case of weld region than that in 

the base material. 

 



Failure Investigation on Failed Towing Arm of An Aircraft: A Case of Improper Material Processing and Failed Repair Welding 

56 

 

Figure 9: Optical microstructures of the failed towing arm end in un-etched condition 

 

 

 

Figure 10: Optical microstructures of the towing arm end in etched condition 

 

 

 

Figure 11: SEM micrographs of the towing arm end near the weld region 



Hazra, M. and Singh, A. K. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 51-66 

57 

The EDS analyses on various phases in the weld zone are presented in Fig. 13. Some precipitates appear to reside 

along the grain boundaries have been found to be rich in Al, Fe and Mn. Eutectic phases contain mainly Al and Si. 

Overall composition of the weld region has been found to be rich in Si and Al (Fig. 14). Base material reveals the 

presence of grain boundaries rich in Cu, Fe and Al (Fig. 15). Defect portions of the grain boundaries contain Si, Cu 

along with Cl and O (Fig. 16). Overall base material composition shows the presence Al along with small amount of 

Cu (Fig. 17). 

 

 

 

 

Figure 12: High magnification SEM images of the weld region and base material 

 

 

 

 

Figure 13: EDS analysis patterns on various phases in the weld zone  

SE BSE 



Failure Investigation on Failed Towing Arm of An Aircraft: A Case of Improper Material Processing and Failed Repair Welding 

58 

 

 

 

 

Figure 14: Overall composition of the weld region as obtained by EDS analysis 

 

 

 
 

Figure 15: EDS analysis on grain boundaries in base material 

 

 

 

 

Figure 16: EDS analysis of defects on grain boundaries in base material  



Hazra, M. and Singh, A. K. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 51-66 

59 

Fig. 18 exhibits SEM micrographs of various locations of the towing arm end away from the failed region. Reference 

image of sample extraction is displayed in Fig. 18(a, b). Presence of thick and continuous grain boundary precipitates 

are quite well revealed in the BSE images (Fig. 18(d, g)). Several microstructural defects related to grain boundary 

cracking and grain pullout have been observed. Fig. 19 exhibits high magnification image of the said region. Two 

types of precipitates have been observed: (i) rich in Cu and Fe and (ii) rich in Cu only. Matrix composition has been 

found to be Al containing  5 wt.% Cu.  

Microstructures of the towing pin are shown in Fig. 20. It reveals the presence of alternate layer of greyish and 

whitish phases. Three different locations marked as 1 (bright contrast), 2 (grey contrast) and 3 (overall composition) 

have been analyzed for composition. The EDS analysis reveals the presence of Fe only in all the three locations (Fig. 

21).  

 

 

 

Figure 17: Overall base material composition as obtained by EDS analysis 

 

 

 

 

Figure 18: SEM micrographs of various locations of the towing arm end away from the failed region 

SE BSE 

SE BSE 



Failure Investigation on Failed Towing Arm of An Aircraft: A Case of Improper Material Processing and Failed Repair Welding 

60 

 
 

Figure 19: High magnification image along with EDS analysis on regions (Fig. 18) 

 

 

 

Figure 20: Optical (a, b) and SEM micrographs (c-e) of towing pin 



Hazra, M. and Singh, A. K. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 51-66 

61 

 

 

Figure 21: EDS analysis patterns on various marked locations 1, 2 and 3 (Fig. 20) 

 

3.5 Chemical Composition 

Composition of towing arm as obtained by XRF is given in Table 1. It shows Cu as the major alloying element apart 

from the base material Al. Towing pin is found to contain only Fe, while the EDS analysis was taken from bulk of the 

sample at low magnification. Compositions of the towing arm and towing pin as obtained from ICP-OES analysis is 

presented in Table 2. Towing arm is found to contain Cu and Si as major alloying elements along with the base Al. 

The analysed composition of towing arm is very close to the alloy B295 [5]. The ranges of the alloying elements in 

alloy B295 is included in Table 2 for ready reference. Towing pin consists of Mn as the major alloying elements along 

with the base Fe. Contents of the trace elements (C and S) of the towing pin are shown in Table 3. 

 

 

Table 1: Chemical compositions of failed towing arm and towing pin as obtained by XRF and EDS techniques. 

 

Component Technique 

Elements (wt.%) 

Cu C Si Ti Ni Fe Al 

Towing arm XRF 4.65 - 0.35 0.15 0.009 0.132 Bal. 

Towing pin EDS - 2.2 - - - 97.8 - 

 

 

Table 2: Chemical compositions of the failed towing arm and towing pin obtained by ICP-OES technique 

 

Component 

Elements, wt% 

(Standard deviation, wt%) 

Fe Ni Cu Si Ti Mn P Al 

Towing Arm 
0.17 

(0.01) 

<0.00

2 

4.3 

(0.1) 

1.03 

(0.06) 

0.13 

(0.05) 
- - Bal. 

B295 [5] Max. 1.0  4.0-5.0 0.7-1.5 Max.0.25 Max.0.35  Bal. 

Towing Pin Bal. - - 
0.58 

(0.06) 
- 

0.82 

(0.06) 

0.037 

(0.003) 
- 

 

 

Table 3: Contents of trace elements (C and S) of the failed towing pin 

 

Elements C S 

wt.% 

(Standard deviation) 
0.19 (0.01) 0.034 (0.002) 



Failure Investigation on Failed Towing Arm of An Aircraft: A Case of Improper Material Processing and Failed Repair Welding 

62 

3.4 Hardness 

Vickers hardness values of towing arm sample taken at 5 kg load are found to be 88, 102, 108, 98, 92, with an 

average value of 98 Hv. The weld region of Towing arm possesses hardness values (taken at 500 g load) of 103.6, 

99.1, 94.2, 104.2, with an average value of 100 Hv. Towing pin possessed hardness value of 230 Hv. 

A micro hardness profile taken along a line across the weld interface and covering both base and weld materials 

has been shown in Fig. 22. Fig. 23 is the reference image for the indentations taken on the sample. Here, one can 

notice that the weld material possesses an average hardness value of 102 Hv, while the same for base material is 116 

Hv. It may be noted that these values are not in agreement with the bulk Vickers hardness values of the two regions 

as mentioned above. 

Hardness value of the interface (measured on the actual interfacial line) is found to be around 100 Hv. The 

hardness value on the weld side ranges from 65 to 130 Hv and gets stabilized at around 2.25 mm (2250 µm) from 

the interface. On the other hand, hardness value spanned from 115 Hv to 125 Hv on the base metal side and gets 

stabilized at around only 1.5 mm (1500 µm) from the interface.  

 

 

 

 

Figure 22: Micro hardness survey (in Vickers scale) across the weld interface 

 

 

 
Figure 23: Reference image for the micro hardness survey across the weld interface 

 

 

4 DISCUSSIONS 

4.1 Material of Construction: Identity and Suitability 

Microstructure, chemical composition and hardness evaluations of the as-received failed components indicate that 

the material of construction of towing arm is a cast Al-Cu-Si alloy (closely matching with B295 alloy in T6 condition), 

while that of the towing pin is a low carbon (mild) steel [5, 6].  Microstructure of the base material consists of α-Al 
(with Cu) along with grain boundary precipitates rich in Al, Fe and Cu and closely matching with Al2FeCu type. The 

material contains defects such as pores and grain fall outs etc. quite extensively throughout its microstructure. The 

choice of the material composition and (casting) process route appear to be usual for the fabrication of towing arm 

wherein requirement of high strength, appreciable amount of ductility at room and elevated temperatures, sufficient 

corrosion resistance along with the involvement of extensive wear and tear is there in service [5-10].   



Hazra, M. and Singh, A. K. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 51-66 

63 

4.2 Repair Welding: Its Presence, Need and Impact upon the Present System 

There are well-defined weld regions around the circumference of the fracture surface of Towing arm. This is supported 

by the visual examinations as well as observation under SEM. Overall compositions of the base and weld materials 

as obtained from the EDS analysis reflects the use of an Al-Si base filler metal in the welding process [5, 7, 8, 11-13]. 

Similar level of hardness values along with gross similarity in microstructure between base and weld materials in the 

failed component indicate that the T6 heat treatment has been given to the component after welding.  

It seems that the repair welding has been carried out to refurbish prior localized failed and detached areas (Fig. 

3a). However, one must notice that the inherent defects in the base material in present case are the cracks along the 

grain boundary precipitates in addition to the pores and grain fallouts. Thus, the avoidance of recurrence of such 

failure by repair welding is not possible, unless it changes the local thermal and/or chemical history to the desired 

extent [13-17]. Intended microstructure resulting from this proposed change in local thermal and/or chemical history 

may find usefulness in such case. However, no such desired changes have been observed in present case, after the T6 

heat treatment given to the whole assembly (base material + weld). Interestingly, weld material has been found to 

contain more defects in terms of pores and cracks than the base. Therefore, adoption of the method of repair welding 

does not seem to suit the purpose of mitigating the existing defects in base material, also assuming that some of those 

defects have been responsible for the failure. 

The grain boundary cracks along Al-Cu-Fe rich precipitates have been found in partially melted zone (PMZ) of 

heat affected zone (HAZ) of the base material, similar to that is observed in locations away from the weld area (i.e. 

pure base material). Introduction of welding has come up with problem of more frequent occurrence of cracking in 

the heat-affected zone (HAZ) of the base material than that at away from it (i.e. pure base material). Grain boundary 

rich in Al-Fe-Mn precipitates and frequent cracking along the grain boundaries has been observed in weld regions 

both in longitudinal as well as transverse welds. 

Thus, in the post-weld condition and during service of the towing arm, cracks seem to have been present along 

Al-Cu-Fe and Al-Fe-Mn-rich grain boundaries, respectively at the HAZ and weld regions. 

 

4.3 Various Weld Crack Types 

There may be usually two types of cracking in aluminium welds – (i) hydrogen induced cracking (HIC) and/or stress 

corrosion cracking (SCC) and (ii) hot cracking [11,13,18,19]. In the present scenario, based on fractographic evidence 

and also the background information, possibility of HIC as well as SCC is zilch [13, 19]. Thus, the existing all the types 

of cracks are basically hot cracks. This is also well supported by the zig-zag crack paths (representative of intergranular 

cracking) and distinctive fractographs typical of hot cracking [13,18]. Now, broadly the four factors are influencing 

hot cracking in aluminium welds: (i) chemistry of base material, (ii) chemistry of filler metal, (iii) thermal stress (arising 

out of shrinkage during solidification) and (iv) mechanical stress (due to joint configuration/restraint) [20-23]. 

Nonetheless, one has control over the factors (ii), (iii) (even (iii) is somewhat dependent on (ii)) and (iv)), once 

chemistry of the base material is fixed by the user. Thus, chemistry of the filler material along with the mixture (base 

+ filler material) as well as joint design may be monitored. The present (hot) crack type includes both solidification 

as well as liquation cracking. The longitudinal crack of importance seen in the weld region (close to the fusion line) 

on the primary fracture plane and spanning the whole length is a prime example of solidification crack (marked as 

secondary crack in Fig. 3). Physical attributes of the crack such as high depth, large length and three-dimensional 

shape indicate it to be the major culprit of the present failure. In other words, the present failure has initiated with 

this deep and lengthy discontinuity. Similar types of solidification cracks are also seen at weld region (close to the 

fusion line) along the transverse welds (Fig. 3g). Small solidification crack well within the weld interior has been 

observed too occasionally (Fig. 3g). Orientation of these cracks has been found to be parallel to the above-mentioned 

longitudinal solidification crack. On the other hand, close examination of the PMZ of HAZ in base material reveals 

the presence of numerous grain-boundary cracks (Fig. 10). These are nothing but the liquation cracks. Solidification 

and liquation cracks at respective weld and HAZ seem to have been often accompanied by the Al-Fe-Mn and Al-Cu-

Fe rich grain boundary precipitates and their cracking. 

 

4.4 Selection of Filler Metal/Alloy 

Somewhat detailed input on welding filler material is worth mentioning here, as no information related to welding 

is available to the user as well as to the investigator.  

Use of an Al-Si based is quite justifiable and subsequently discussed. The base Al-Cu-Si (or more specifically, Al-

Cu) system has a wide range of crack sensitivity with respect to the Cu content [11-13]. Thus, the use of autogenous 

welding as well as the introduction of filler material of composition similar to the base material is highly risky. This 

is for the reason that doing so would result in the same or enhanced level of crack sensitivity to the system. Widely 

popular filler metals of 4xxx (Al-Si based) and 5xxx (Al-Mg based) series are common choices in Al welding. 

Interestingly, the alloys of 4xxx series help in diluting the ill effect of Cu locally in this regard. Problem of shrinkage 

related thermal stresses is quite low in this case. On the other hand, filler materials of 5xxx series aggravate the 

cracking tendency by combined poorly effect of Cu and Mg on the coherency temperature range.   



Failure Investigation on Failed Towing Arm of An Aircraft: A Case of Improper Material Processing and Failed Repair Welding 

64 

Failure Mechanism 

The Sequence of Failure 

Schematic diagram consisting of a proposed sequence of events is shown in Fig. 24. This (Fig. 24a) is described with 

reference to the whole fracture surface presented in Fig. 3h. Longitudinal three-dimensional crack front spanning the 

whole length of the weld, close to fusion line is formed as a result of residual stresses coming out of joint constraint 

and/or heat treatment. This has disturbed the integrity of the joint and thus the component at the beginning of its 

service operation. This crack front has a curved surface area and extends from location at considerable depth to its 

opening up at the obtained fracture surface. This, later on, moves towards (both upward and downward) transverse 

directions (marked as inclined arrows) on the presently obtained plane of fracture surface. Advanced stage of its 

propagation on the fracture plane is indicated by big inclined arrows. On the other hand, material becomes weakened 

by the presence of liquation cracks in HAZ (indicated by small straight arrows). Thus, these liquation cracks indirectly 

have assisted in the present failure by easing the crack propagation stage. Similarly, small (longitudinal) and 

moderately big (transverse) solidification cracks in transverse welds have assisted the current failure by weakening 

the microstructure. Varying proportions of the final stages of failure are observed in transverse and longitudinal 

welds. Weld section 1 is proposed to possess the least area fraction of the final stage of failure. This is due to the 

consumption of its greater amount by the above said three-dimensional solidification crack front. This is much 

commensurate with the visual examination (Fig. 3) as well as with the fractographic evidence (Figs. 5 and 7). 

 

 
 

Figure 24: Schematic diagram showing a proposed sequence of events leading to failure 

 

Contribution of Joint Design, System and/or Service Stresses [13, 18, 20-23] 

There is absence of uniform weld thickness along the four sides of the failed surface, as mentioned earlier. This may 

have led to the unequal distribution of the system and/or service stresses and thus aggravating the early likelihood of 

the failure. 

Surrounding fixtures during welding operation has an effect in the present case of weld cracking. Solidification 

cracks have been observed at welds close to the fusion lines at both the longitudinal as well as the transverse sides. 

Small solidification cracks aligned along the major axis (i.e., along the longitudinal side on the fracture plane) are also 

observed within the weld. It is quite clear from the results reported so far, that there has been a dominance of 

transverse stress over its longitudinal counterpart, as is supported by the frequent occurrence of (solidification) cracks 

of considerable depth and length, aligned along the longitudinal side. The proposed schematic also corroborates the 

same in the primary fracture plane which is formed by the movement of longitudinal solidification crack front towards 

the transverse direction only (Fig. 24). 

It is also possible that the residual longitudinal and transverse stresses may be present. This may well come from 

the joint configuration and/or heat treatment of the component after welding. 

 

Contribution from Service Stress 

Failure extending towards the side (transverse) weld zones has exhibited cleavage type of brittle fracture during final 

stage of failure. This is purely a result of overload. The signature of other types of load is not observed. Presence of 

cleavage during last stage of failure in both transverse as well as longitudinal weld zones (1, 1
/
, 2 and 2

/
 in Fig. 24) in 

spite of presence of weak intergranular regions (causing solidification cracking) indicate the involvement of rapid rate 

of loading due to very thin weld areas as compared to the remaining regions of the failed surface.  

 

Microstructural Contribution 

The inherent weakness of the parent material such as grain boundary cracks, pores, grain fall outs etc. has still been 

found to be present at failure location (weld zone, HAZ) as well as at location away from the failure (i.e. unaffected 

parent base material). Thus, the inherent metallurgical weaknesses of the material still prevail and sometimes have 



Hazra, M. and Singh, A. K. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 51-66 

65 

been aggravated subsequent to the welding (as manifested by more frequent occurrence of the above defects). Thus, 

the T6 condition of the component material in parent state as well as in as-weld condition does not appear to suit 

for the present component. 

A three-dimensional weld solidification cracking has been found to be the primarily responsible for the creation 

of primary fracture plane in the present failure. This is also supported by the existence of secondary cracks in the 

weld zone having trajectory and orientation similar to the fracture path, as mentioned above. Grain boundary cracks 

at the HAZ (often typified by grain fallout) arising out of the liquation cracking have assisted the present failure. 

Solidification and liquation cracking have been found to be accompanied with grain-boundary precipitates rich in Al-

Cu-Fe and Al-Fe-Mn at the weld and HAZ, respectively. 

Longitudinal weld side in the final failure reveals the presence of cleavage signs with occasional occurrence of 

cleaved facets within the moderately well revealed predominantly intergranular fracture (Figs. 5 and 7). On the other 

hand, clear disclosure of the cleavage signature along with cleaved facets and faintly revealed two-dimensional 

intergranular channels have been noticed on the transverse weld side during the final stage of failure. Thus, 

predominance of traits of cleavage fracture has been noticed especially along the transverse welds unlike along the 

longitudinal welds. Interestingly, this phenomenon indicates that the Al-Fe-Mn rich precipitates along the grain 

boundaries in weld region are not so week so as to lead a completely intergranular fracture (as in transverse welds), 

unless there is a co-existence of solidification cracks along with those precipitates (as in longitudinal welds). The 

longitudinal weld (weld section 1 in Fig. 24) is thin enough during final stage of failure. This has resulted in non-

revelation of cleavage (type of signature of the overload) failure. This low thickness of the final zone of failure is due 

to the presence of the deep solidification crack of three-dimensional nature extending towards longitudinal weld 

periphery of the fracture surface at the component edge. 

Thus, it is noteworthy from the ongoing discussion so far that precipitates located in base material and HAZ as 

well as rich in Al-Cu-Fe are possibly relatively softer than those in weld zone and rich in Al-Fe-Mn. This results in the 

more active participation of Al-Cu-Fe along with the liquation cracking in aggravating the present failure than that 

of the Al-Fe-Mn along with the solidification cracking phenomenon. 

 

5 CONCLUSIONS 

5.1 Towing Arm 

1. The present failure appears to have occurred by cracking of the weld region of the towing arm fork, as a result 

of introduction of weld repairing process as a method of healing of prior existing defects and/or failure at the 

location of weld area. 

2. Primary reason of the weld cracking and failure is the existence of solidification cracks at weld region close to 

the fusion line (HAZ-weld interface), while liquation cracks at partially melted zone (PMZ) in heat affected zone 

(HAZ) has contributed to it secondarily by weakening the overall microstructure. 

3. Grain boundary precipitates of Al-Cu-Fe type have facilitated development of the liquation cracking, while grain 

boundary precipitates of Al-Fe-Mn type seem to have resisted the intergranular failure in solidification cracking, 

under the combined actions of welding induced stresses and service stresses. 

4. Improper material processing has led to the weakening of the microstructure of the base material by 

introduction of pores, grain fall out, thick Al-Cu-Fe type of continuous grain-boundary precipitates and cracking. 

5. Weld repairing appears to be not successful at all on the Al-Cu-Si system in the present condition; rather it has 

aggravated the previously existing improper material condition. 

 

5.2 Towing Pin 

Mild (low carbon) steel with low strength level could not bear with the load of the fractured assembly of the towing 

arm and thus got bent. Its failure is of secondary nature and importance with respect to the failure of towing arm 

fork and the whole assembly. 

 

6 RECOMMENDATIONS 

1. Material Related: Pre-existing (casting related) defects such as porosity, grain fall-outs need to be optimized and 

to be guided by well-defined specification. 

2. Repair Welding Related: The repair welding, if unavoidable, should be practised with the following precautions. 

3. Process Related: Process should be monitored based on internationally popular standards for aeronautical 

applications such as AMS 2175 and AMS-A-21180 [11, 14-17, 19, 24, 25].  

4. Minimization of Residual Stress and Associated Cracking: Joint design and fixturing should be such that there 

would be insufficient amount of residual stresses both in longitudinal as well as transverse directions so as not 

to crack the weld afterwards. Post weld heat treatment (PWHT) may be employed to minimize the ill effect of 

residual stresses [18, 19, 20-23, 25]. 



Failure Investigation on Failed Towing Arm of An Aircraft: A Case of Improper Material Processing and Failed Repair Welding 

66 

ACKNOWLEDGEMENTS 

The authors would like to thank Dr G. Madhusudhan Reddy, Director, DMRL for his constant encouragement to 

work on the present field. Also, funding from DRDO is gratefully acknowledged. 

 

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